Post on 19-Jul-2020
Khin Mar Kyu, Myat Shwe Wah &
Moe Moe Aye
Department of Physics
University of Yangon
Myanmar (19 Dec 2014)
Theme : 4
Introduction to Energy
Energy Efficiency& Energy Conservation
Sectors of EE
Energy Saving
Energy Efficiency Project in Myanmar
Energy
Nature of Energy
Different Types of energy
Forms of Energy Energy conversions Energy Transfer
Different Types of energy sources
Energy and Environment
Energy is all around you!◦ You can hear energy as sound.◦ You can see energy as light.◦ And you can feel it as wind.
You use energy when you:◦ hit a softball.◦ lift your book bag.◦ compress a spring.
Living organisms need energy for growth and
movement.
Energy is involved when:◦ a bird flies.◦ a bomb explodes.◦ rain falls from the sky.◦ electricity flows in a wire.
The five main forms of energy are:
Heat
Chemical
Electromagnetic
Nuclear
Mechanical
All forms of energy can be converted into other forms. The sun’s energy through solar cells can be
converted directly into electricity. Green plants convert the sun’s energy
(electromagnetic) into starches and sugars (chemical energy).
Chemical
Electrical
Sound(mechanical)
Light(Electromagnetic)
ThermalMechanical
Fossil fuels
Renewable sources
Nuclear sources
coal, petroleum, and natural gas
solar, wind, hydroelectric, biomass, and geothermal power
Fission and fusion
Advantages Disadvantages
Moderate existingsupplies
Large potentialsupplies
High costs
Low net energyyield
Large amount ofwater needed toprocess
Severe land disruption fromsurface mining
Water pollution from mining residues
Air pollution when burned
CO2 emissionswhen burned
Easily transportedwithin andbetweencountries
Efficientdistributionsystem in place
Coal
Low risk of accidents because of multiple safety systems (except in 35 poorly designed and run reactors in former Soviet Union and Eastern Europe)
Moderate land use
Moderate landdisruption andwater pollution(without accidents)
Emits 1/6 asmuch CO2 as coal
Lowenvironmentalimpact (withoutaccidents)
Large fuelsupply
Spreads knowledge and technology for building nuclear weapons
No acceptable solution for long-term storage of radioactive wastes and decommissioning worn-out plants
Catastrophic accidents can happen (Chernobyl)
High environmental impact (with major accidents)
Low net energy yield
High cost (even with large subsidies)
Advantages Disadvantages
Nuclear Power
Advantages DisadvantagesFairly high netenergy
Work on cloudydays
Quick installation
Easily expandedor moved
No CO2 emissions
Low environmentalimpact
Last 20-40 years
Low land use(if on roof or builtinto walls or windows)
Reducedependence on fossil fuels
Need accessto sun
Low efficiency
Need electricitystorage system or backup
High land use (solar cell power plants) could disrupt desert areas
High costs (but should becompetitive in5-15 years)
DC current must be converted to AC
Solar Power
Improve Energy Efficiency
Increase fuel-efficiencystandards for vehicles,buildings, and appliances
Mandate governmentpurchases of efficient vehicles and other devices
Provide large tax credits for buying efficient cars, houses, and appliances
Offer large tax credits for investments in efficiency
Reward utilities forreducing demand
Encourage independentpower producers
Greatly increase efficiencyresearch and development
More Renewable Energy
Increase renewable energy to 20% by 2020 and 50% by 2050Provide large subsidies and tax credits for renewable energyUse full-cost accounting and least-cost analysis for com-paring all energy alternativesEncourage government purchase of renewable energy devicesGreatly increase renewableenergy research and development
Reduce Pollution andHealth Risk
Cut coal use 50% by 2020
Phase out coal subsidies
Levy taxes on coal and oil use
Phase out nuclear power or put it on hold until 2020
Phase out nuclear power subsidies
CoalOil(Crude)Natural GasNuclearAmbientSolarHydroWindWave
GeothermalBio-energy
EnergyUsers
HeatingElectricityGas(N.G)S.N.G.C.N.G.Liquid Fuels
Conversion&
DistributionIndustries
HeatingLightingPowerTransport
PRIMARY DELIVERED USER
Environment
Consumption of Goods and Services
Production of Goods and Services
Resources Recovery
Waste Disposal
Resources and Energy
Energy
Wastes and Energy
Goods and Services
Waste and Energy
Consumption WasteResources and Energy
Recycling
Wastes and Energy
Buildings
Industry
Transport
heating systemslighting systems process heat
processescompressed air systemsheat recoveryelectrical energy use
carslorriesshipstrainsaircraft etc.
Now and in the future!
Save Energy
Reduce costs
Protect the environment
Energy efficiency is "using less energy to provide the
same service".
Energy efficiency is not energy conservation.
Energy conservation is reducing or going without a
service to save energy.
For example: Turning off a light is energy
conservation. Replacing an incandescent lamp with a
compact fluorescent lamp (which uses much less energy
to produce the same amount of light) is energy
efficiency.
EGEE 102 - S. Pisupati 19
If we are more efficient with the energy wealready have there will be less pollution, lessreliance on foreign oil and increaseddomestic security.
Energy Efficiency
Introduction to EE
Definition of EE
Energy Efficiency of heat engine
CARNOT’s ENGINE
Improvement of energy efficiency
Environment & EE
Saving energy not only helps the planet, it helpsyour pocketbook as well.
Saving energy reduces our nation’s overall demandfor resources needed to make energy, andincreasing your energy efficiency is like addinganother clean energy source to our electric powergrid.
An energy-efficient home will keep your familycomfortable while saving you money.
EE may be the key to Saving Trillions.
Environmental Economic Utility System Benefits Risk Management
Energy efficiency (η) is the radio of the output work
(energy) to the input work (energy).
“ Output energy is always lower than input energy.”
WorkInput WorkOutput η =
23
Energy Conversion
Device
Energy Input
Useful Energy Output
Energy Dissipated to the Surroundings
InputEnergyTotalOutputEnergyUsefulEfficiency =
EGEE 102 - S. Pisupati 25
InputEnergyTotalOutputEnergyUsefulEfficiency =
An electric motor consumes 100 watts (a joule per second (J/s)) of power to obtain 90 watts of mechanical power. Determine its efficiency ?
= 90 W x 100 = 90 %100 W
Engine efficiency of thermal engines is therelationship between the total energycontained in the fuel, and the amount ofenergy used to perform useful work. Thereare two classifications of thermal engines-
Internal combustion (gasoline, diesel and gasturbine, i.e., Brayton cycle engines) and
External combustion engines (steam piston,steam turbine, and the Stirling cycle engine)
EGEE 102 - S. Pisupati 27
A heat engine is any device which converts heat energy
into mechanical energy.
Accounts for 50% of our energy conversion devices
Temperature is in ° Kelvin !!!!!!!
For a coal-fired utilityboiler, The temperatureof high pressure steamwould be about 540°Cand T cold, the coolingtower water temperaturewould be about 20°C.
Calculate the Carnotefficiency of the powerplant ?
540 ° C = 540 +273 ° K = 813 °K20 °C = 20 + 273 = 293 °K
EGEE 102 - S. Pisupati 29
Overall Eff = Electric Energy Output (BTU) x 100Chemical Energy Input (BTU)
= 35 BTU x 100100 BTU
= 35%Overall Efficiency of a series of devices =(Thermal Energy)x(Mechanical Energy) x(Electrical Energy)Chemical Energy Thermal Energy Mechanical Energy
= E boiler x E turbine x E generator= 0.88 x 0.41 x 0.97= 0.35 or 35%
Fig: Thermal efficiencies of various types of small to medium sized diesel and gas engines
Fig: Improvement in gas turbine efficiency
Environment and Energy Efficiency
Cost reductions through efficient use of energy
Reduced exposure to fluctuating energy supply and
prices and blackouts
Increase in productivity and product quality
Improved reputation with customers and society
through environmental protection
Improved employee motivation, health and safety
Compliance with legislation and ISO 14001 targets
• High efficiency is good for economy and the environment
• High efficiency is in line with core business electricity
industry
– reducing emissions (protection environment)
– conservation fuels (preservation of resources)
– reducing dependence on fuel import outside EC
• Too high efficiencies are expensive and thus uneconomic:
– market advantage to less efficient (=cheaper) plants
– thus not beneficiary for the environment
Reduces home and business energy costs
Improves productivity
Reduces energy market prices
Stimulates economic growth
Improves energy system reliability
Reduces criteria air pollutant emissions
Enhances national energy security
Energy Efficiency
Different Sectors of Energy Efficiency
Household sector & Residential sector
Industrial sector
Transportation sector
Household sector & Residential sector
A household is defined as a group of persons who share the sameliving accommodation, who pool some, or all, of their income and wealthand who consume certain types of goods and services collectively,mainly housing and food.
Members of the same household do not necessarily have to belong tothe same family so long as there is some sharing of resources andconsumption.
Students who study away from home are still part of a household. Excluded are:
◦ Hired domestic staff who live on the same premises;◦ People who live permanently in institutions (religious orders, mental
hospitals, prisons, retirement);
More than 90 million single-family, multifamily, and mobile
home households encompass the residential sector.
Households use energy to cool and heat their homes, to
heat water, and to operate many appliances such as
refrigerators, stoves, televisions, and hot tubs.
The energy sources utilized by the residential sector
include electricity, natural gas, fuel oil, kerosene, liquefied
petroleum gas (propane), coal, wood, and other renewable
sources such as solar energy.
Clothes Washers
Dishwashers
Refrigerators
Room Air Conditioners
TVs, VCRs, Audio Equipment
Home Heating and Cooling Products
New Homes
Windows
Residential Lighting Fixtures
Roof Products
Insulation
See http://www.energystar.gov/ for more details
The residential and commercial sectors include all homes andcommercial businesses (excluding agricultural and industrialactivities).
IncandescentCompact
Fluorescent
500 lbs. of coal
What’s the difference?
•1,430 lbs. CO2 pollution avoided •$30 saved
We can make some simple substitutions
Replacing just 1 incandescent light bulb with 1 compact florescent bulb saves about 150 pounds of carbon dioxide per year!
If every American household replaced just 5 high-use incandescent
bulbs with compact florescent lights we'd collectively save more than
$8 billion each year in energy costs and we would prevent the
greenhouse gases equivalent to the emissions from nearly 10 million
cars.Source: http://www.energystar.gov
Well-insulated Walls & Attic
Upgrade or Replace Windows
Plant Shade Trees & Shrubs
Replace Furnace
Improve Hot Water System
Replace Lightbulbs w/ CFLs or LEDs
replacing Refrigerator
Schedule an Energy Audit
Primary Secondary
Tertiary Quaternary
Industry is the sector of the economy concernedwith the production of goods and services.
46
PRIMARYSECONDARY
TERTIARY
QUATERNARY: Research is carried out in to new ways of processing or growing cotton. e.g. organic cotton.
Cotton is grown and picked on a cotton farm Cotton is processed to
cloth, which is, in turn, sewn in to clothing.
Cotton clothes (eg jeans, shirts etc) are sold in high
street shops.
COTTON IN THE FASHION INDUSTRY...
47
Increase the life of products.
Optimize recycling.
Improve industrial processes, where possible.
Educate managers to integrate efficiency into
plant management
The largest reductions of industrial energyconsumption will come from returning to aculture of thrift.
Improving process efficiency requiresengineering advances.
Improving non-process efficiency requires abetter doctrine of plant management.
Objective
Energy Efficiency in Transportation Sector
◦ Energy Losses in a Vehicle
◦ The Best Ways to Conserve Energy in Transportation
◦ Environmental Actions in the Transport Sector
◦ Tips to Save Energy in Transportation
Streets, highways, and transit systems thatallow people and goods to move safely andefficiently
◦ Backbone for a strong economy
◦ Key contributor in quality of lifeHow many types of transportation can you name?
53
There are many types of transport that are used on the land.
We can see many different types of transport in the sky.
We can see many different types of transport in the water.
World Oil Consumption per Sector
1973
Transport42%
Industry27%
Non Energy Use
6%
Other Sectors25%
2004
Industry10%
Non Energy Use17%
Transport58%
Other Sectors15%
42% 58%
+16%
TRANSPORT SECTOR RELEVANCE
(IEA, 2006)
Oil dependency; Congestion; Poor air quality in urban
centers.
Toxic pollutants such as SOX and NOX, CO and unburned hydrocarbons
Fossil fuels (coal, oil, natural gas)
Carbon Dioxide (CO2)
Global warming due to CO2 emissionCombustion (burning)Fuel(C,H)+O2 CO2 + CO + H2O + energy(heat)
Vegetable Oils (Future Ethyl Ester)
Vegetable Oils (Methyl Ester)
Propane
Natural Gas
Methanol
Hydrogen (Renewable)
Hydrogen (From NG)
Ethanol (Future)
Ethanol (Now)
Electricity
Gasoline & Diesel Fuel
25 50 75 100
Zero
Zero or a Credit
Zero
Myanmar
FY 2002 GHG emissions in Japan
•Predictions say temperatures will increase between 1.4-5.8 C innext 100 years•Small changes in average temperatures make a big difference
Decline Energy Intensity
Increasing Energy Consumption
Economic Vehicle Population
Population
Fuel Efficiency Transport
Sector
Economic Strategic Social Environmental
The concept of "efficiency" must be put in its properplace;
It is entirely value-driven.
Value implications depend on who the customer is.
Value judgements are inherent in everymeasurement decision, because one must definewhat measures what concept.
Yet fuel prices are important especially with regardto efficiency.
(Fuel economy )how far a vehicle can travel per unit of fuel
burn less gas
use less oil
Fuel efficient vehicles
cut global warming emissionsproduce less pollution
miles per US gallon → L/100 km: 235 / mpgUS = L/100 kmmiles per Imp. gallon → L/100 km: 282 / mpgImp. = L/100 km
L/100 km → miles per US gallon: 235 / (L/100 km) = mpgUS
L/100 km → miles per Imp. gallon: 282 / (L/100 km) = mpgImp.
Engine efficiency of thermal engines is the relationshipbetween the total energy contained in the fuel, and theamount of energy used to perform useful work. Thereare two classifications of thermal engines-
Internal combustion (gasoline, diesel and gas turbine,i.e., Brayton cycle engines) and
External combustion engines (steam piston, steamturbine, and the Stirling cycle engine).
Energy efficiency
is similar to fuel
efficiency but the
input is usually in
units of energy
such as
British thermal
units (BTU),
j l (MJ)
"energy intensity", or the amount
of input energy required for a unit
of output such as MJ/passenger-
km (of passenger transport),
BTU/ton-mile (of freight
transport, for long/short/metric
tons),
GJ/t (for steel production),
BTU/(kW·h) (for electricity
generation), or
litres/100 km (of vehicle travel).
Litres per 100 km
Gasoline new passenger car fuel efficiency
Country 2004 average
Requirement2004 2005 2008 Later
People's Republic of China[20]
6.9 L/100 km
6.9 L/100 km
6.1 L/100 km
United States
24.6 mpg (9.5 L/100 km) (cars and trucks)*
27 mpg (8.7 L/100 km) (cars only)*
35.5 mpg (6.6 L/100 km) (2016)
European Union
5 L/100 km (2012)
Japan[10]6.7 L/100 km CAFE eq(2010)
Australia[10]8.08 L/100km CAFE eq (2002)
none
6.7 L/100 km CAFE eq(2010) (voluntary)
Vehicle fuel efficiency and Engine efficiency aredetermined by the technical energy efficiency;
Vehicle travel denotes the type of travel/driving andthe number of miles driven;
Vehicle population is the number of vehicles on theroad.
Eroad transport = (vehicle fuel efficiency) x (vehicle travel) x (the vehicle population)
Source: www.fueleconomy.govUS DOE
•87.4 % of fuel energy is wasted
•Only 12.6 % of fuel energy is transferred to the wheels
•5.8 % is turned to kinetic energy, consumed in the brake
•17.2 % idling losses, engine on with no torque69
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2
1BA VVmE −=
A B
A B
• VB > VA accelerating, fuel is consumed, kinetic energy is increased
• VA > VB braking, vey little fuel is consumed, kinetic energy is reducedenergy is dissipated in the brakes as heat in conventional cars
In hybrids braking energy is recovered by an electric generator and stored in a batteryit is called regenerative energy, or “Regen Energy”
Driving Force
mghE =
Need engine power, fuel is consumed, potential energy is increased
no need for engine power
Braking, vey little fuel is consumed, potential energy is reduced energy is dissipated in the brakes as heat in conventional cars
In hybrids braking energy is recovered, Engine can be turned off automatically going downhill
Driving Force
ÖL
+ Additives
+ Additives
Blending with5 - 12differentComponents
DifferentCrude Oilsand Refineries
ParaffinsNaphtensAromaticsOlefins
AromaticsParaff./Napht.OlefinsOxygenates
+ Air Different Combustion NOxHC
SO2
C6H6 PAHPM
COCO2
Gasoline
Diesel
Formulation ?
Formulation ?